Intracellular polysaccharide of an anaerobic psychrophile <Emphasis Type="Italic">Clostridium algoriphilum</Emphasis>

Polysaccharide was revealed in the cytoplasm of spore-forming Clostridium algoriphilum 14D1 = VKM B-2271 = DSM 16153 grown on glucose at 5°C. This polymer was isolated, purified, and identified as a glycogen-like compound based on analysis of its hydrolysis products. The ratio of the polysaccharide to the dry biomass weight did not change in the course of culture growth. Limitation of C. algoriphilum 14D1 growth by nitrogen resulted in a doubling of the polysaccharide/dry biomass ratio. The transition of C. algoriphilum 14D1 cells from optimal conditions into carbon-free medium resulted in utilization of intracellular polysaccharide. The amount of polysaccharide was shown to depend on glucose concentration, type of the carbon substrate, and growth temperature. Future investigations of polysaccharide functions in C. algoriphilum 14D1 cells are discussed.     

Effects of amino acids on polysaccharide synthesis ofEscherichia coli K-12lon + andlon − strains

Ultraviolet-sensitivelon ^? mutant ofEscherichia coli K-12 produced abundant polysaccharide when grown in a minimal medium at 37 C, but not when grown in a broth medium. The repression of polysaccharide synthesis in the broth-grownlon ^? andlon ⁺ cells was studied. The effects were largely dependent on the amino acid concentrations and on the requirements of the strain used. At 200 μg per ml of each of the essential amino acids, histidine, proline, and threonine, there was complete inhibition of polysaccharide synthesis. At 200 μg per ml the required amino acids, tryptophane and tyrosine promoted polysaccharide synthesis. Most amino acids inhibited cell growth at 200 μg per ml but the inhibiting effect was smaller at 400 μg per ml. Polysaccharide synthesis of cells was not correlated with the growth rate, and occurred even under non-growing conditions.     

Formation of exopolysaccharides by Rhodococcus erythropolis and partial characterization of a heteropolysaccharide of high molecular weight

Summary Polysaccharide formation by Rhodococcus erythropolis was studied using lower mono-, di-and trihydric alcohols, sugars and n-alkanes as carbon sources. Cultural conditions of the organism were examined with regard to polysaccharide production. It was demonstrated that a glycerol substrate, an 30°C incubation temperature and a pH of 7.5 were optimal cultural conditions for polysaccharide formation. Addition of penicillin G in the decelerating growth phase increased the polysaccharide concentration in the culture filtrate to 3.1 g/l. One of the main extracellular heteropolysaccharides formed by Rhodococcus erythropolis consisted of glucose and mannose in the molar ratio 11, a small portion of protein and a trace of glucosamine. The molecular weight was to be 1·14×10⁶.     

Biological,chemical and physical factors influencing the seasonal change of polysaccharide concentration in irrigation-channel sediment

Variation of polysaccharide concentration in irrigation-channel sediment was determined concurrently with biological, chemical and physical factors influencing the benthic algal community. Phenol-sulphuric acid method was used to measure polysaccharide concentration. Polysaccharide concentration, biomass of benthic algae, and species composition changed spatially and temporally. Fluctuations of total suspended solid (TSS) concentration and exposure of channel bed to direct sunlight had major effects on algal growth and polysaccharide production. Polysaccharide concentration was correlated to chlorophyll a concentration (r=0.73, P<0.001) and algal biomass (r=0.57, P<0.001). Fragilaria construens and Aulacoseira (Melosira) italica were the most common diatoms in the benthic flora. Chlorophyll a concentration in the sediment showed a strong negative correlation (r=-0.99, P<0.001) with the seasonal variation of TSS concentration in channel water. The polysaccharides produced by benthic microorganisms play a major role in clogging channel bed and thereby reducing seepage from earthen irrigation channels. Correlations between polysaccharide concentration and chlorophyll a (and algal biomass) further indicate the importance of benthic algae for polysaccharide production. Since availability of light to the algal flora is critical for the production of polysaccharides, the effect of clogging can be maximized by exposing the channel bed to direct sunlight during non-irrigation period (winter).     

Kinetics of polysaccharide B-1459 fermentation

Polysaccharide gum was made by fermentation with Xanthomonas campestris NRRL B-1459 in a medium of glucose, minerals, and distillers' solubles. The effect of distillers' solubles on growth rate can be described by the familiar saturation equation. Although a quasistoichiometric relationship was observed between nitrogen utilization and growth, total nitrogen supply was not growth limiting, nor was polymer formation growth associated. Cell growth primarily took place in the early part of the fermentation; polysaccharide biosynthesis occurred throughout the fermentation. Glucose was converted to polysaccharide at a fairly constant yield, which was 70–80% of glucose consumed, under optimum conditions. The kinetic patterns observed indicate that multistage continuous fermentation will be suitable for polysaccharide production.     

The production and release of an extracellular polysaccharide during starvation of a marine Pseudomonas sp. and the effect thereof on adhesion

A marine Pseudomonas sp. S9 produced and released an extracellular polysaccharide during complete energy and nutrient starvation in static conditions. The presence of the polysaccharide on the cell surface, demonstrable by immune transmission electron microscopy, correlated with changes in the degree of adhesion to hydrophobic surfaces. Polysaccharide coated cells showed a lower degree of adhesion than did cells devoid of the polymer. After 10 h of starvation, no ruthenium red stained antibody stabilized polysaccharides could be observed on the cell surface. The polysaccharide was not produced during growth since lysates of mid-log phase cells did not precipitate the antiserum. The relative proportions of sugars in the polysaccharide were 28% glucose, 35% N-acetylglucosamine and 37% N-acetylgalactosamine. The released polysaccharide did not significantly alter the physical parameters of surface tension and viscosity of the starvation regime. Cells starved in agitated conditions did not produce any extracellular polysaccharides and exhibited a different adhesion pattern to hydrophobic surfaces.Non-standard abbreviations FSS Four salt solution - GLC gas liquid chromatography - MS Mass spectrometry - NSS nine salt solution     

Correlation between extracellular polysaccharide composition and nodulating ability inRhizobium trifolii

Summary Two auxotrophic mutants ofRhizobium trifolii which are deficient in nodulating ability have been isolated. Both mutants (strain RS 164 His^– and strain RS213 Leu^–) appear to synthesize abnormal extracellular polysaccharides as compared with the wild type strain RS 55. Simultaneous recovery of nodulating ability and wild type polysaccharide composition has been found in a Leu⁺ revertant of strain RS 213.Abbreviation EPS Extracellular Polysaccharide - NIG N-Methyl-N-Nitro-N-Nitrosoguanidine     

Effect of temperature on bacterial gellan production

The effect of temperature on the production of the polysaccharide gellan by the bacterium Sphingomonas paucimobilis ATCC 31461 was studied in relation to carbon source. When glucose served as the carbon source, gellan formation by the strain was highest after 72 h of growth at an incubation temperature of 30–31 °C. Polysaccharide production by the sphingomonad cells grown on corn syrup for 72 h was maximal at an incubation temperature of 31 °C. The highest cellular productivity in elaborating gellan was observed at 31 °C after 72 h of growth independent of the carbon source utilized.     

Production of polysaccharide hydrolases in the genusRhizopus

Polysaccharide hydrolase activity was assayed in a group of 28 selectedRhizopus strains. The production of lichenases, mannanases, cellulases, xylanases, amylases and pullulanases was demonstrated using the gel-testing method during growth of the strains on suitably meshed polysaccharide gels.     

Simplified Microassay for Pullulan Synthesis

A simple radiometric microassay for extracellular polysaccharide elaboration by yeast-like cells of Aureobasidium pullulans was developed, based upon a procedure originally described by Catley (FEBS Lett. 20:174-176, 1972). Incorporation of [¹⁴C]glucose into pullulan was linear with respect to time and cell dose. The pH and temperature optima for elaboration were 5.3 and 30°C, respectively. Polysaccharide elaboration declined linearly with culture age.     

Screening,production, optimization and characterization of cyanobacterial polysaccharide

Biotechnological applications of algal polysaccharide as emulsifiers, thickeners and laxatives have led to the screening and selection of certain diazotrophic filamentous cyanobacteria from saline/alkaline soil of Madhya Pradesh, India. Strain specific variation in cell bound, extracellular and total polysaccharide content was quantified under laboratory conditions. Among the cyanobacterial isolates examined Nostoc calcicola RDU-3 was found to produce highest amount (105 mg l⁻¹) of extracellular polysaccharide on 44th day of growth under diazotrophic growth conditions. Extracellular polysaccharide production of cyanobacterium Nostoc calcicola RDU-3 was optimal at pH-10, temperature 35°C, photoperiod of 24 h and in white light. The Gas Chromatographic analysis of polysaccharide from Nostoc calcicola RDU-3 revealed the presence of ribose (36.03%), xylose (34.13%), rhamnose (29.67%) and glucose (4.0%). The polysaccharide is novel in that it possesses ribose as the predominant monosaccharide with very low levels of glucose. Predominance of ribose monosaccharide is the unique feature which is reported to be used as metabolic supplement to the heart. IR spectrum of extracellular polysaccharide revealed the presence of sulphate group. Such sulphated polysaccharide is reported to have antiviral properties.     

Effects of photon flux density,CO2, aeration rate,and inoculum density on growth and extracellular polysaccharide production byPorphyridium cruentum

Growth and extracellular polysaccharide production byPorphyridium cruentum were measured as a function of several culture parameters. Photon flux density of 75 μmol m⁻² s⁻¹ and CO₂ concentration of 2.5% were found to be optimum for both growth and extracellular polysaccharide production. Interactive studies on these two parameters further confirmed that at these levels of photon flux density and CO₂, when applied together, both growth (5.9·10⁷ cells per mL) and extracellular polysaccharide production (1.9 g/L) were at the maximum. Maximum growth and extracellular polysaccharide production were observed at inoculum density of 10⁶ cells per mL and aeration rate of 500 mL air per min per liter.     

Microalgal polysaccharide production for the conditioning of agricultural soils

Summary Two species of mucilaginous green algae,Chlamydomonas mexicana andC. sajao, were evaluated forin situ production of polysaccharides in untilled samples of selected agricultural soils. Greenhouse experiments indicated that the moisture content of the soils must be maintained near 100% of field capacity to permit growth of the algae. The algae increased the polysaccharide content of the uppermost 2 mm of soil by 20% to 129%, but in only 3 treatments out of 12 was there any significant increase in soil polysaccharide content at the 3–8 millimeter depth. More than 99% of the algal cells and most of the polysaccharide produced by the algae remained in the top 2 millimeters of soil. The results suggest that although these algae can increase the polysaccharide content of the uppermost strata, where soil crust formation may present problems in agriculture, frequent irrigation is necessary to maintain algal growth. Tillage would be necessary to incorporate the algal polymers for soil conditioning at depths greater than 2 millimeters.     

The endogenous metabolism ofFibrobacter succinogenes and its relationship to cellobiose transport,viability and cellulose digestion

Fibrobacter succinogenes S85 digested ballmilled cellulose at a rapid rate (0.10 h^–1), but there was a long lag time if the culture was not transferred daily. WhenF. succinogenes was starved for 100h, a large fraction of the cells (>30%) still bound to cellulose, but the lag time was 150h. The lag time was similar for either cellulose- or cellobiose-grown inocula, and lag times were highly correlated (r ² = 0.91) with a decrease in viable cell number. The number of viable cells declined from 10⁸ to 10⁶ in the first 30h of starvation, and by 72h the viable cell number was less than 10³/ml. Cells growing exponentially on cellobiose had a large pool of polysaccharide, and continuous culture experiments indicated that polysaccharide accumulation was not significantly influenced by the growth rate of the culture (approximately 0.7 mg polysaccharide mg^–1 protein). When the cellobiose was depleted, cellular polysaccharide decreased at first order rate of 0.09 h^–1. The rate of endogenous metabolism was initially 0.08mg polysaccharide mg^–1 protein h^–1, and there was little decline in viability until the rate of endogenous metabolism was less than 0.01 mg polysaccharide mg^–1 protein h^–1. When the rate was less than 0.01 mg polysaccharide mg^–1 protein h^–1, the cells could not maintain a sodium gradient, transport cellobiose or grow. The endogenous metabolic rate needed for cell survival was 20 fold less than the maintenance energy of cells growing in continuous culture (0.01 versus 0.232mg carbohydrate mg^–1 protein h^–1).     

INFLUENCE OF GROWTH STATUS AND NUTRIENTS ON EXTRACELLULAR POLYSACCHARIDE SYNTHESIS BY THE SOIL ALGA CHLAMYDOMONAS MEXICANA (CHLOROPHYCEAE)1

Increased levels of nitrogen in liquid growth medium bring about increased growth and a delay in extracellular polysaccharide production by Chlamydomonas mexicana Lewin on a per-cell basis. Addition of nitrogen to stationary phase cultures causes renewed growth and a temporary lag in polysaccharide synthesis until growth again ceases. Removal of nitrogen terminates growth, causing an immediate increase in polysaccharide synthesis. Phosphate-starved cells show a response similar to nitrogen-starved cells, indicating that the beginning of stationary phase and not nitrogen depletion causes the stimulation in extracellular polysaccharide synthesis. As similar results are assumed to occur on soil, the significance of this response is discussed.     

Polysaccharide microarrays for high-throughput screening of transglycosylase activities in plant extracts

Polysaccharide transglycosylases catalyze disproportionation of polysaccharide molecules by cleaving glycosidic linkages in polysaccharide chains and transferring their cleaved portions to hydroxyl groups at the non-reducing ends of other polysaccharide or oligosaccharide molecules. In plant cell walls, transglycosylases have a potential to catalyze both cross-linking of polysaccharide molecules and grafting of newly arriving polysaccharide molecules into the cell wall structure during cell growth. Here we describe a polysaccharide microarray in form of a glycochip permitting simultaneous high-throughput monitoring of multiple transglycosylase activities in plant extracts. The glycochip, containing donor polysaccharides printed onto nitrocellulose-coated glass slides, was incubated with crude plant extracts, along with a series of fluorophore-labelled acceptor oligosaccharides. After removing unused labelled oligosaccharides by washing, fluorescence retained on the glycochip as a result of transglycosylase reaction was detected with a standard microarray scanner. The glycochip assay was used to detect transglycosylase activities in crude extracts from nasturtium (Tropaeolum majus) and mouse-ear cress (Arabidopsis thaliana). A number of previously unknown saccharide donor-acceptor pairs active in transglycosylation reactions that lead to the formation of homo- and hetero-glycosidic conjugates, were detected. Our data provide experimental support for the existence of diverse transglycosylase activities in crude plant extracts.     

Polysaccharide Elicitor from the Endophyte <i>Bionectria</i> sp. Fat6 Improves Growth of Tartary Buckwheat under Drought Stress

Drought can limit the growth and reduce the yield of crops, but the safe and effective bio-approach to improve the drought resistance of crops is very little. We conducted an experiment in which we monitored the effects of polysaccharide from the endophyte Bionectria sp. Fat6 on the growth of Tartary buckwheat (Fagopyrum tataricum (L.) Gaertn) seedlings under control and drought-stressed conditions by determining gas exchange, photosynthesis parameters, photosynthetic pigment contents, and metabolite accumulation. Results indicated that the polysaccharide from endophyte stimulated plant growth and increased the aboveground biomass, root mass, and root/shoot ratio of Tartary buckwheat. Application of the polysaccharide to drought-stressed plants resulted in a significant increase in the net photosynthetic rate, stomatal conductance, and transpiration rate of Tartary buckwheat and decreased the intercellular CO₂ concentration. The contents of chlorophyll a, chlorophyll b, chlorophyll a + b, and carotenoids in leaves were higher in polysaccharide-treated seedlings than that in control. Polysaccharide notably increased the soluble protein and proline content and decreased the malondialdehyde content in Tartary buckwheat leaves. The endophytic polysaccharide may protect Tartary buckwheat against drought by improving leaf gas exchange and photosynthetic capacity, and altering concentrations of protective metabolites. Together, these changes may compensate for the negative impacts of drought stress on the growth of Tartary buckwheat. Thus, the polysaccharide from the endophyte Bionectria sp. Fat6 may be an effective biotic elicitor and a promising bio-approach to improve Tartary buckwheat production worldwide.     

Chemical characterization and radioprotective effect of polysaccharide from <Emphasis Type="Italic">Monostroma angicava</Emphasis> (Chlorophyta)

Polysaccharide from the green alga Monostroma angicava was extracted with boiling water and was purified by ion-exchange and size-exclusion column chromatography. The radioprotective effect of the polysaccharide was investigated in mice. The results show that polysaccharide from M. angicava has a different chemical composition to other Chlorophyta having a high rhamnose – containing sulfated polysaccharide. The sulfate ester content was estimated to be 21.8%. When the polysaccharide was applied to BALB/c mice following whole-body X-ray irradiation the counts of leukocytes, thrombocytes and erythrocytes recovered more rapidly in the polysaccharide treated mice after irradiation. In the irradiated mice, the polysaccharide significantly increased the spleen index, natural killer cytostatic activity and the transformation response of splenic lymphocytes. The present observations suggest that polysaccharide from M. angicava led to leukocytogensis and hematopoetic activation in mice after irradiation and that the biological response might be caused by immune activation.     

胞外多糖产生菌的筛选鉴定及其促生改土作用

【背景】一些微生物具有较强的产胞外多糖潜力,在改良盐碱土壤、促进作物生长方面潜力巨大。【目的】筛选耐盐碱且产胞外多糖的微生物,为开发具有盐碱土壤改良效果的菌剂提供菌种资源。【方法】从滨海盐碱植物根际土中筛选可在盐碱土壤中增殖、产胞外多糖、解有机磷和钾等能力的微生物菌株,并通过形态、生理生化、基于16S rRNA基因序列和gyrB基因的分子鉴定确定菌株类别,分析该菌株的生长、产胞外多糖特性受盐碱胁迫的影响,考察该菌对盐碱土壤不同粒径团聚体比例的影响,并结合盐碱土壤番茄种植试验考察对植物生长指标和土壤指标的影响。【结果】从727株滨海盐碱土壤菌株中筛选出一株产胞外多糖、具有较强盐碱土壤增殖能力且能解有机磷和钾的芽孢杆菌GBW HF-98,确定该菌为枯草芽孢杆菌沙漠亚种(Bacillus subtilis subsp. inaquosorum)。该菌可耐受pH值达10.0和NaCl浓度达110 g/L,在改善轻和中盐度土壤中不同粒径团聚体比例的效果较为显著。该菌的高剂量浓度T2组,在中度盐碱土壤的番茄种植试验中,与对照相比显著增加了壮苗指数、根干重、全株干重、茎粗和株高等指标,增幅分别为33.8%、59.3%、37.2%、12.3%和15.6% (P<0.05);显著降低pH、全盐含量和土壤容重,降幅分别为8.9%、27.9%和17.9%;显著提升土壤速效磷和速效钾指标,增幅分别为36.0%和17.4% (P<0.05)。【结论】GBW HF-98菌株具有较强的胞外多糖产生能力,在中度盐碱土壤中促进番茄生长和改良土壤的效果显著,可用于盐碱土壤改良菌剂的研制。     

Morphology,cell growth,and polysaccharide production of <Emphasis Type="Italic">Nostoc flagelliforme</Emphasis> in liquid suspension culture at different agitation rates

Noscoc flagelliforme is a terrestrial macroscopic cyanobacterium with high economic value. Free-living cells that were separated from a natural colony of N. flagelliforme were cultivated in a 20-L photobioreactor for 16 days at five agitation rates with impeller tip speeds at 0.3, 0., 0.8, 1.0, and 1.5 m·s⁻¹. With different impeller tip speeds there were significant differences in the cell growth and polysaccharide production, and different types of cell colonies appeared because of different shear forces caused by agitation. At harvest time, cell concentrations with tip speeds of 0.8 and 1.0 m·s⁻¹ were clearly higher than those with the other three tip speeds, but dry cell weights with the tip speeds of 0.3, 0.5, 0.8, and 1.0 m·s⁻¹ were almost the same. The highest RPS (polysaccharide that released into liquid medium) production was obtained with the tip speeds of 0.8 and 1.0 m·s⁻¹, while the highest EPS (polysaccharide that formed capsule or slime layer) production was obtained with the tip speed of 0.5 m·s⁻¹. The tip speed of 1.5 m·s⁻¹ was harmful for both cell growth and polysaccharide production, indicating that an appropriate shear force was needed in the liquid suspension culture of N. flagelliforme.